Finite-size inertial spherical particles in turbulence

TL;DR

This study uses direct numerical simulations to explore how spherical particles of varying size and density influence turbulence, revealing different energy transfer mechanisms and flow modulations based on particle properties.

Contribution

It provides new insights into the effects of finite-size inertial particles on turbulence, including their impact on energy transfer, flow anisotropy, and clustering behavior.

Findings

Large and light particles modulate all flow scales isotropically.

Small and heavy particles influence large scales and alter energy transfer mechanisms.

Particle size and density significantly affect flow intermittency and clustering.

Abstract

We investigate by direct numerical simulations the fluid-solid interaction of non-dilute suspensions of spherical particles moving in triperiodic turbulence, at the relatively large Reynolds number of $Re_\lambda \approx 400$. The solid-to-fluid density ratio is varied between $1.3$ and $100$, the particle diameter $D$ ranges between $16 \le D/\eta \le 123$ ($\eta$ is the Kolmogorov scale), and the volume fraction of the suspension is $0.079$. Turbulence is sustained using the Arnold-Beltrami-Childress cellular-flow forcing. The influence of the solid phase on the largest and energetic scales of the flow changes with the size and density of the particles. Light and large particles modulate all scales in a isotropic way, while heavier and smaller particles modulate the largest scales of the flow towards an anisotropic state. Smaller scales are isotropic and homogeneous for all cases. The mechanism driving the energy transfer across scales changes with the size and the density of the particles. For large and light particles the energy transfer is only marginally influenced by the fluid-solid interaction. For small and heavy particles, instead, the classical energy cascade is subdominant at all scales, and the energy transfer is essentially driven by the fluid-solid coupling. The influence of the solid phase on the flow intermittency is also discussed. Besides, the collective motion of the particles and their preferential location in relation with properties of the carrier flow are analysed. The solid phase exhibits moderate clustering; for large particles the level of clustering decreases with their density, while for small particles it is maximum for intermediate values.